DE102005035104C5 - Furniture drive with encoder - Google Patents

Abstract

Electromotive drive (1), in particular a furniture drive, comprising: - an axially adjustable adjusting element (6) guided in a guide device (4), which is connected to a first fastening element (7) for articulation to a furniture part to be adjusted; - A spindle (9) with a with the adjusting element (6) coupled to the spindle nut (10); - Limit switch (12) for scanning end positions of the drive (1); and - in the guide means (4) arranged means for scanning the displacement of the adjusting element (6) as an absolute encoder which is coupled to the adjusting element (6) and - that the means for scanning the adjustment a support rail (13) with at least two conductor tracks (29a to c), of which at least one has a certain electrical resistance; and a slider contact (34) arranged in a slider carrier (14), which contacts the conductor tracks (29a to c) of the carrier rail (13), the electrical resistance of the conductor tracks (29a to c) being ...

Description

The invention relates to an electromotive drive, in particular a furniture drive, with a guided in a guide device, axially adjustable adjustment according to the preamble of claim 1.

Such electric motors are known for applications, for example, for adjusting furniture parts of beds, treatment chairs and the like, wherein their rotational movement is converted via a transmission, preferably a so-called spindle / spindle nut transmission in a linear motion. The execution of such a motor can be a DC or AC motor, for example with a flanged worm gear.

In such adjustable furniture, for example in beds or treatment chairs, it is necessary to reproducibly recover certain adjustment positions, such as a stand-up and / or sitting position. This is the case in particular with multiple drives, since a reproducible adjustment of this number of drives is very cumbersome. For this purpose, it is known to equip the furniture or the drives with a position detection.

A known solution is the use of incremental encoders, which are mounted on the drives or the adjusting elements. Their position information must be stored in non-volatile electronic storage devices, since otherwise the position information is lost after switching off the electrical power supply, whereby a reproducible setting of previously assumed positions is impossible. These control devices are complicated by the number of components ago and therefore not always economical.

In addition, with a manual quick adjustment of the drive, for example in case of power failure or emergencies in nursing and hospital area, through a so-called unlocking between drive and adjustable furniture part, the coupling with the encoder also solved and the position information is lost.

Other solutions are the use of capacitive and inductive encoders, which are suitable only for a limited length of adjustment.

Another solution is known by means of variable resistances, so-called potentiometer. Here, for example, a potentiometer is coupled by means of a gear with the drives. However, the transmission must be as free of play as possible. The potentiometer can also be designed in a multi-start design. The gearbox usually requires precise assembly work. Furthermore, a gear must be adapted to different lengths adjustment paths, with additional storage costs for many different parts is required. As an example to illustrate the document DE 196 03 318 A1 serve.

A use of so-called Linearpotentiometern in adjusting drives is known. However, these linear potentiometers are only available in a very limited number of different adjustment paths, so that the range of application for adjusting drives is very narrow. Special dimensions of these components lead to economic disadvantages and high inventory.

The DE 200 05 065 U1 describes a Doppelschneckenstirnradantrieb in which in the flange guide a linear potentiometer is used. This linear potentiometer can perform position detection in conjunction with an incremental encoder. If an incremental encoder is used alone or in conjunction with the potentiometer, a movement can not be detected in the event of a power failure. Furthermore, the evaluation of the path recognition is complicated because at the same time still the direction of movement must be detected. In addition, this reference does not specify how the linear potentiometer is to be mounted, and how it is constructed, so that one can assume that the commercial linear potentiometer should be used, but require a large installation space and only in a few lengths are available.

In the DE 43 16 142 A1 a linear drive is shown, which is equipped with tracks and sliding contacts. The conductor tracks are arranged parallel to the movement path of the linearly movable parts of the spindle nut combination. These electrically conductive strip conductors extend at least over the range of movement of the spindle nut combination. In addition, sliding contacts are provided which are connected to the linearly movable part. For this purpose, depending on the embodiment, the conductor track is provided with means for interrupting the electrical contact at a first position and at a second position. In addition, the tracks are connected to the electrical connection of the motor or a relay control with diodes, so that the motor current can be switched or controlled at the first or at the second position. In this linear drive, the resistance of the conductor tracks is low or he moves to the zero state and beyond it is constant over the entire length of the conductor, so that a distance measurement can not be done by a change in resistance. Besides, the contact between the Grinder and the conductor track at the first position and interrupted at the second position, so that an evaluation of the adjustment often can not be done.

In the DE 43 20 204 A1 An actuator for a hydraulically actuated automotive clutch is described. For this purpose, an electric motor actuates a hydraulic piston of a master cylinder via a screw drive. The pressure oil acts on a slave cylinder of the friction clutch. In this case, a position sensor is provided, which is summarized together with the master cylinder in a structural unit. The length of the position sensor and the housing size are designed as fixed lengths and sizes, so that only with changes in the housing of the actuator and the position sensor, the actuator is adaptable to other adjustment paths.

The invention has the object to provide an easy-to-install electric motor drive with an absolute encoder, which is adaptable to any length of an adjustment of such a drive housing without or only with slight changes of the drive housing and the position information remains in the drive even with a quick release ,

The object is achieved in conjunction with the preamble of claim 1 according to the invention by the characterizing features of claim 1.

• – ein in einer Führungseinrichtung (4) geführtes, axial verstellbares Verstellelement (6), das mit einem ersten Befestigungselement (7) zur Anlenkung an ein zu verstellendes Möbelteil verbunden ist;
• – eine Spindel (9) mit einer mit dem Verstellelement (6) gekoppelten Spindelmutter (10);
• – Endschalter (12) zur Abtastung von Endpositionen des Antriebs (1); und
• – eine in der Führungseinrichtung (4) angeordnete Einrichtung zur Abtastung des Verstellwegs des Verstellelements (6) als ein absoluter Weggeber, der mit dem Verstellelement (6) gekoppelt ist und
• – dass die Einrichtung zur Abtastung des Verstellwegs eine Trägerschiene (13) mit mindestens zwei Leiterbahnen (29a bis c) aufweist, von denen mindestens eine einen bestimmten elektrischen Widerstand aufweist; und
• – einen in einem Schleiferträger (14) angeordneten Schleiferkontakt (34), der die Leiterbahnen (29a bis c) der Trägerschiene (13) kontaktiert, wobei der elektrische Widerstand der Leiterbahnen (29a bis c) in Abhängigkeit von der Position des Verstellelements (6) eingestellt ist, dadurch gekennzeichnet, dass die Leiterbahnen (29a bis c) auf einer ablängbaren Trägerschiene (13) aufgebracht sind, und wobei der in der Trägerschiene (13) axial geführte Schleiferträger (14) mit dem Verstellelement (6) gekoppelt angeordnet und ausgebildet ist, – dass der Schleiferträger (14) mit der Spindelmutter (10) formschlüssig verbindbar ausgebildet ist, und – dass die formschlüssige Verbindung des Schleiferträgers (14) mit der Spindelmutter (10) mittels eines Verbindungselements (22) ausgebildet ist.

The invention provides an electric motor drive, in particular a furniture drive, which has the following:

• - one in a management organization ( 4 ) guided, axially adjustable adjusting element ( 6 ), which with a first fastener ( 7 ) is connected for articulation to a furniture part to be adjusted;
• - a spindle ( 9 ) with one with the adjusting element ( 6 ) coupled spindle nut ( 10 );
• - limit switch ( 12 ) for scanning end positions of the drive ( 1 ); and
• - one in the management facility ( 4 ) arranged device for scanning the displacement of the adjusting element ( 6 ) as an absolute displacement sensor, which with the adjusting element ( 6 ) is coupled and
• In that the device for scanning the adjustment path is a carrier rail ( 13 ) with at least two tracks ( 29a to c), of which at least one has a certain electrical resistance; and
• - one in a slider carrier ( 14 ) arranged grinder contact ( 34 ), the conductor tracks ( 29a to c) the carrier rail ( 13 ), wherein the electrical resistance of the conductor tracks ( 29a to c) depending on the position of the adjusting element ( 6 ), characterized in that the conductor tracks ( 29a to c) on a lengthenable carrier rail ( 13 ) are applied, and wherein in the carrier rail ( 13 ) axially guided grinding carriers ( 14 ) with the adjusting element ( 6 ) is arranged and formed coupled, - that the slider carrier ( 14 ) with the spindle nut ( 10 ) is formed positively connectable, and - that the positive connection of the grinding carrier ( 14 ) with the spindle nut ( 10 ) by means of a connecting element ( 22 ) is trained.

This embodiment has the particular advantage that the device for scanning the displacement in the form of an absolute displacement sensor is designed as a abwegable rod material, wherein advantageously it is simply possible to shorten the carrier rail forming the encoder to any required length.

Here, the slider carrier is formed positively connected to the spindle nut, resulting in an advantageous simple and quick installation.

It is expedient that the positive connection of the wiper carrier is formed with the spindle nut by means of a connecting element, wherein the connecting element has a spherical head which is formed in a corresponding receptacle of the wiper carrier introduced, as a result not only a slight attachment, but also a balance Of assembly and manufacturing tolerances of the associated components advantageously easy.

In a preferred embodiment, the connecting element is formed on a switching ring, which is coupled to the spindle nut. Hereby, it is advantageously possible to always connect different spindle nuts with different types of threads with the same design of the adjusting ring.

A preferred embodiment of the electromotive drive, wherein the drive further comprises a releasable locking between the first fastening element and the adjusting element, is characterized in that the switching ring and the spindle nut are formed rotatable relative to each other. This makes it particularly easy to get a rotation of the spindle nut with respect to the switching ring and the drive by an applied adjusting force at a quick adjustment.

Preferably, the embodiment in which the switching ring is guided with its outer shell in the guide means and the outer diameter of the switching ring is greater than the outer diameter of the spindle nut.

In this embodiment, it is advantageously prevented by an indirect guidance of the spindle nut via the switching ring in the guide device that a scoring occurs on the spindle nut, which aggravates a rotation of the same in a quick adjustment or even blocked.

A further embodiment provides that the switching ring is provided with at least one engagement element for engagement and for axial fixing with the spindle nut. This is advantageously achieved simply that the axial movement of the spindle nut is transmitted to the switching ring and thus to the displacement sensor, wherein at the same time a rotation of the spindle nut against the rotationally guided switching ring is made possible.

In a preferred embodiment, the switching ring is clipped on the spindle nut, resulting in an advantageous quick and easy installation.

In a further embodiment, the ablängbare carrier rail is provided at one end with terminals for electrical connection of the conductor tracks, wherein the opposite end of this end is cut to length. This makes it possible in a simple manner that an evaluation circuit is not to be adapted to different Weggeberlängen, but it is always present, for example, for the adjustment of the initial position, the same resistance of the encoder. Only the maximum value is different, since it depends on the length of the encoder. The ratio of path change to resistance change always remains the same.

Another embodiment provides that the ablängbare end of the support rail is formed for electrical connection of the interconnects with each other. This makes it possible to use the tracks of the carrier rail either as a simple variable resistor or as a voltage divider by the latter, the tracks are electrically connected to the cut end of the support rail, which also easy connection of the other end of a conductor to form a voltage divider results.

In a preferred embodiment, the interconnects of each end of the carrier rail for electrical connection of the interconnects with each other and / or for electrical connection to a control and evaluation unit by solder, plug and / or squeeze contacts are formed. This ensures that the connection of the tracks to evaluation can be done easily and easily, with the production times are shortened.

It is expedient that the carrier rail or the guide device forms a conductor track, since this advantageously reduces the number of additional conductor tracks to be applied.

In a preferred embodiment, the interconnects are integrated in a circuit as a variable resistor or as a voltage divider, it being of great advantage that the ratio of path change to resistance change is designed to remain constant, since thereby cutting the carrier rail with the tracks not on the area between the lower position and the current position.

The ratio of path change to change in voltage of a voltage divider circuit is designed to be constant, which advantageously provides a proportional relationship between the adjustment path and the resistance change.

In a further embodiment, the voltage difference between the respective end positions of the slider carrier is formed substantially constant regardless of the length of the carrier rail. This makes it possible to design an advantageously simple evaluation of the resistance values.

The invention will now be explained in more detail with reference to the accompanying drawings with reference to an embodiment. Hereby shows:

1 a perspective view of an electric motor drive in an embodiment of an embodiment of the invention;

2 the drive after 1 in a partial exploded view;

3 an enlarged view of the section A from 1 ;

4 a perspective view of an embodiment of a spindle nut of the embodiment according to the invention 2 ;

5 a longitudinal section through the spindle nut after 4 ;

6 a plan view of the spindle nut after 4 ;

7 a perspective view of another embodiment of a spindle nut of the embodiment according to the invention 2 ;

8th the spindle nut 4 in a perspective exploded view;

9 a plan view of the drive according to the section line XX after 1 ; and

10a -C are schematic representations of embodiments of a position encoder of the present invention.

In 1 is an electric motor drive 1 illustrated in perspective in an exemplary embodiment. The drive 1 consists of a motor 2 that is connected to a gearbox 3 is grown. The motor 2 Here is a well-known DC motor in the low voltage range. The gear 3 is connected at its top with a profiled in this example tube made of plastic or metal, which serves as a guide device 4 referred to as. The management device 4 is on its top with a cover 5 provided by which an adjusting element 6 extends upwards through. The adjusting element 6 is at its upper end with a first fastener 7 equipped, which is provided for articulation to a piece of furniture to be adjusted (not shown). A second fastener 8th is at the bottom of the gearbox 3 attached and also serves to articulate to a piece of furniture with the furniture part to be adjusted. The adjusting element 6 is in the direction of the longitudinal axis of the drive 1 (see arrow) moved to adjust the furniture part axially.

In 2 is the drive 1 out 1 without guide device 4 shown, with other components are shown for clarity in an extended position. The motor 2 drives over the transmission 3 , preferably a worm gear, a spindle 9 to, whose rotational movement in a known manner via a spindle nut 10 in an axial adjustment movement of the adjusting element 6 is implemented. The spindle nut 10 is at the lower end of the adjusting element 6 mounted rotatably connected thereto and is within the guide device 4 axially guided, which will be described in more detail below. Because the adjusting element 6 by means of the first fastening element 7 rotatably connected to the furniture part, is also the spindle nut 10 rotatable about this connection and can rotate the spindle 9 perform an axial movement.

The adjustment or stroke of the adjustment 6 is caused by stops and / or limit switches 12 limited, which in this example of the spindle nut 10 be actuated upon reaching the respective end position, whereby the engine 2 is turned off. It is in 2 only the upper limit switch 12 shown, another limit switch for the lower end position is not shown. The limit switches are on a ledge 11 (see also 3 and 9 ), which are inside the guide device 4 parallel to the longitudinal axis of the spindle 9 and the adjusting element 6 is arranged. Next to this bar 11 is also parallel to the longitudinal axis of the spindle 9 a carrier rail 13 arranged, on which conductor tracks 29a to c (see 3 . 9 and 10 ), which are in operative connection with a slider carrier 14 and a wiper contact 34 (please refer 9 and 10 ), with the wiper contact 34 in or under the slider carrier 14 is arranged resiliently to a constant contact pressure on the conductor tracks 29a to exercise c.

The slider carrier 14 is in turn at the spindle nut 10 attached and is with it axially parallel to the longitudinal axis of the spindle 9 with adjustment of the drive 1 adjusted.

3 shows an enlarged section A from 2 , The tracks 29a to c are inside the carrier rail 13 from each other and against the carrier rail 13 applied in isolation. At least one of the tracks 29a to c has a certain electrical resistance, that of the length of the respective conductor track 29a until c is dependent. The resistance is preferably proportional to the length of the respective conductor track 29a formed to c.

The slider carrier 14 will be in the carrier rail 13 axially guided. His grinder contact 34 is in each adjustment in electrical connection with the tracks 29a to c of the carrier rail 13 and forms with them a variable electrical resistance. This electrical resistance is applied to terminals a, b, c of the conductor tracks 29a to c preferably fed to the lower end of the support rail via known, not shown electrical connection means of an evaluation.

The electrical resistance is thus dependent on the position of the wiper contact 34 in the slider carrier 14 , with the spindle nut 10 and the adjusting element 6 connected, whereby he depends on the adjustment of the drive at the same time 1 is trained. A specific position or stroke corresponds in each case to a specific electrical resistance value at the terminals a, b, c of the conductor tracks 29a to c.

The carrier rail 13 , the tracks 29a to c and the slider carrier 14 with the wiper contact 34 form a so-called linear potentiometer in the form of an absolute encoder. This means that after turning off the power of the drive 1 the relation between resistance value and position of the adjusting element 6 is always guaranteed.

This linear potentiometer can advantageously be used as a cut-to-length component for many different stroke lengths of drives 1 come into use. Advantageously, the terminals a, b, c at the lower end of the carrier rail 13 arranged so that it can be shortened in its upper portion to any required extent, wherein the resistance values for the lower end position and from this on the displacement of the adjusting element 6 always the same. This means that a cutting to length of the carrier rail 13 and thus the tracks 29a until c only changes the maximum resistance corresponding to the upper end position of the total travel of the respective drive. The ratio of travel path change to resistance change remains with all drives 1 same with different stroke lengths.

Below is with reference to 10 this variable resistance or this linear potentiometer thus formed explained in more detail.

The firm connection of the adjusting element 6 with the first fastener 7 In a preferred embodiment, it may be designed to be releasable or releasable and to be lockable again, in order to ensure rapid adjustment of the furniture part without actuating the motor 2 of the drive 1 For example, in an emergency, when a so-called quick adjustment by hand in medical furniture is required. This can by external force on the adjustment 6 this with the spindle nut 10 opposite the first fastening element 7 be relatively twisted, so that an adjustment is possible. Because the slider carrier 14 of the linear potentiometer on the spindle nut 10 is fixed, the linear potentiometer is also changed in this manual adjustment, whereby always the current position corresponding resistance value of the linear potentiometer the next time the drive 1 remains guaranteed.

The connection of the slider carrier 14 with the spindle nut 10 can be designed in different ways. 4 shows a spindle nut 10 with an internal thread 16 having spindle nut body 15 , which is preferably cylindrical and on which a switching ring 20 is applied. This switching ring 20 is with the spindle nut body 15 , as 5 in longitudinal section, by means of at least one engagement element 25 connected, which in one in the lower portion of the spindle nut body 15 introduced groove 18 (please refer 8th ) intervene. The engagement element may be on the lower circumference of the shift ring 20 be arranged several times. It is inside on a preferably resilient tab of the shell of the switching ring 20 formed, wherein the tab by cuts in the longitudinal direction of the switching ring 20 can be formed.

At its upper end, the switching ring is internally provided with a recess into which a corresponding circumferential collar 17 of the spindle nut body 15 intervenes. Through this engagement and the connection between engagement elements 25 and groove 18 is the switching ring 20 axially on the spindle nut 10 established. The switching ring 20 can thus be advantageous for mounting simply on the spindle nut body 15 be deferred and clipped. The switching ring 20 However, it is radial with respect to the spindle nut body 15 movable to the relative rotational movement of the spindle nut in the above-described quick adjustment 10 to enable.

The switching ring 20 has at least one switching nose on its outer surface 21 for actuating the limit switches 12 on. Furthermore, at her guide elements 23 arranged at a certain angle to each other, the one guide in longitudinal grooves of the guide device 4 allow and prevent rotation of the switching ring in axial adjustment. Near the switching nose 21 is a connecting element 22 arranged, which has a spherical head in a preferred embodiment and the connection with the slider carrier 14 allows, in which this connecting element in a corresponding receptacle 28 (please refer 8th ) intervenes.

The switching ring 20 forms in this embodiment, an axial sliding element for the spindle nut body 15 opposite the guide device 4 , so that the spindle nut body 15 is advantageously preserved against sliding grooves, which may be caused by the sliding within the guide means and, for example, in a quick adjustment of the drive 1 the relative rotational movement of the spindle nut 10 hindered or even prevented.

An alternative embodiment of the spindle nut 10 shows 7 , Here, the spindle nut body 15 ' two circulating leagues 17 ' and 17 '' at a certain axial distance from each other, the one spindle nut section 19 specify on which a switching ring 20 ' is clipped on. This switching ring 20 ' has switching nose 21 , Connecting element 22 and guide elements 23 as described above (not shown). In a preferred embodiment, the outer diameter of the switching ring 20 ' larger than the outer diameter of the spindle nut body 15 ' so these are not in the guide device 4 to be led.

8th shows the embodiment of the 4 to 6 in an exploded view. Here is the connecting element 22 with its ball head for connection to the slider carrier 14 to recognize the side of this on the switching ring 20 can be clipped or inserted for positive connection. The ball head of the connecting element 22 advantageously makes it possible to compensate for tolerances in the adjustment of the drive, which may consist of out-of-roundness, unevenness and inaccuracy of components. Thus, a uniform adjustment of the slider carrier is advantageous 14 and therefore the linear potentiometer guaranteed.

Furthermore, the wiper carrier has 14 in this embodiment, a mounting hole 27 for the slider contact attached on its underside 34 in this mounting hole 27 is introduced from below.

The slider carrier 14 indicates at its the switching ring 20 opposite bottom two leading edges 26 on, parallel to the longitudinal axis of the spindle 9 run and between them a space in the longitudinal direction of the Schleiferträgers 14 specify in which the wiper contact 34 is included. The leading edges 26 become inside the carrier rail 13 led, like 9 represents.

The recording 28 for the engagement of the connecting element 22 is in an upper portion of the grinder body 14 arranged, which is at an angle to a vertical of the surface to the switching ring 20 extends, this reference surface from the undersides of the leading edge 27 of the slider carrier 14 is formed. This angle is dependent on the inner profile of the guide device 4 as below with reference to 9 is described. There can be several shots 28 one behind the other in the longitudinal direction of the slider carrier 14 be arranged to a great degree of flexibility with respect to differently formed switching rings 20 to get.

In 9 is a cross section of the guide device 4 along the section line XX 1 shown. This cross-section has in the upper imaged area a semicircular shape which extends downwardly in successive straight sides, which are connected at the bottom by a web. Inside the guide device 4 extend different reinforcing ribs and guide webs 30 parallel to the longitudinal axis of the guide device 4 , which is perpendicular to the drawing plane here. The guide bars 30 serve on the one hand to guide the guide elements 23 the Schalring 20 or the spindle nut 10 , and on the other hand for guiding the outer shell of the switching ring 20 or the spindle nut 10 , Furthermore, the profile of the guide device 4 two parallel to the longitudinal axis of the guide device 4 extending chambers, of which a first chamber 31 for receiving the limit switches 12 and their bar 11 serves as a profile bar here 33 is trained. Actuators of the limit switches are to the switching ring 20 turned and are by its switching nose 21 pressed when reached.

The next to the first chamber 31 arranged second chamber 32 is on its outside by an elongated wall of the guide device 4 educated. The second chamber 32 is U-shaped and also has a second leading edge 36 on which a guide for a first leading edge 35 that forms on the carrier rail 13 is formed. The carrier rail 13 is in the second chamber 32 arranged so that its open side with the conductors 29a to c to the interior of the guide device 4 points. On both sides of the opening of the carrier rail 13 are first leading edges 35 formed. They serve as a guide for the slider carrier 14 who with his leading edge 26 between them and the inner surface of the support rail 13 in the longitudinal direction of the carrier rail 13 is arranged axially displaceable.

The slider carrier 14 is with its upper part with the connecting element 22 the Schalring 20 positively connected, said upper part at the same or approximately the same angle to the underside of the slider carrier 14 is inclined, form the side edges of the profile of the guide means with a line of symmetry of the profile.

Within the lower area of the slider carrier 14 is the slider contact 34 arranged. The wiper contact 34 consists in a simple advantageous embodiment of an electrically conductive and spring-loaded element, the electrical connection to at least two conductor tracks 29a to c in the carrier rail 13 manufactures. The wiper contact 34 may consist of several components, wherein an at least electrically insulating part of the electrically conductive part at a defined distance from the conductor tracks 29a leads to c, or wherein an electrically conductive part of the electrical connection of the conductor tracks 29a to c produces. With reference to 10 Different versions will be explained in more detail.

The slider carrier 14 can also be from the leadership facility 4 he can also be part of the adjustment 6 be.

The carrier rail 13 is made in a preferred embodiment as a rod with a normalized length, which is shortened to the length required in each case. It may be made of different materials, such as a material used as a substrate for printed circuits, such as Pertinax, epoxy, and the like. It can also be designed as a printed circuit or from an aluminum extruded profile.

The resistance material of the conductor tracks 29a to c is insensitive to oils, fats and moisture. For this purpose, suitable evaluation circuits are also connected.

10a to d shows different versions of the displacement sensor 37 in an embodiment of the respective conductor tracks 29a to c in the upper half of the 10a to d, and in the respective lower part of the associated circuit diagrams.

10a represents a variable resistor made of a trace 29a with a high resistance with connection a and a trace 29b exists as the power supply for the wiper contact 34 serves and has a low electrical resistance with connection b. The wiper contact 34 touches the tracks with contact points 38 , It is in the direction of the double arrow proportional to the adjustment of the adjustment 6 (not shown) thus moves and changes the total electrical resistance between terminals a and b.

In 10b is the conductor track 29b also designed with a high electrical resistance, resulting in easy production of the tracks and a high resolution is possible with small strokes.

The explanations after 10a and b can easily at the end of the carrier rail 13 , which is opposite to the terminals a, b, c, to be cut to length.

10c shows the execution of the tracks 29a to c as a voltage divider or potentiometer. Here is the upper end of the resistor track 29a via a conductor track 29c connected to port c. The wiper contact 34 connects the tracks 29a and 29b , In this version must after cutting to length of the support rail 13 an electrically conductive connector between the tracks 29a and 29c be applied.

10d finally shows a variation in which two resistor tracks 29a and 29c on the carrier rail 13 are applied, with an additional trace 29b is present for the Schleiferzuleitung. Moreover, through a connector, similar to in 10c , a voltage divider can be formed by this connector (dashed line) the upper ends of the tracks 29a and 29c connects electrically.

Thus, an electric motor drive 1 created, which has an absolute encoder, which is arranged in the guide device and is formed in an advantageously simple manner to different adjustment by simply cutting to length. The housing or the guide device 4 of the drive 1 does not have to be changed, complex backlash-free gears are not necessary. Each length, ie adjustment length, can be equipped with this version.

It is conceivable that the management device 4 has other profile shapes.

The carrier rail 13 may be formed as a continuous material on a roll, the required length of which can be unrolled and cut off in an advantageously simple manner during production.

It is also conceivable that the carrier rail 13 has prefabricated predetermined breaking points and thus can be abbreviated in an advantageous simple manner by breaking.

Also, the support rail 13 Wear additional components, such as limit switches, proximity switch for end position of the drive 1 , as well as guide elements for the slider carrier 14 and / or the wiper contact 34 , as well as coupling elements for the adjustment 6 ,

It is also conceivable that the management device 4 consists of more than one part, for example, two halves. The coupling between the slider carrier 14 and the adjusting element 6 can be done by locking mechanical entrainment or sticking of magnetic drivers.

The carrier rail 13 can be made of a flexible printed circuit board material and thus in non-linear guide devices 4 be used. In this case, the adjustment is 6 a rotating part, which generates a pivoting or a reciprocating movement of a furniture part via a coupling element. Here is the adjustment 6 be designed as a wheel, which, for example, a clutch hub and a driver for the slider carrier 14 wherein the slider carrier 14 is guided along an arcuate track along.

The carrier rail 13 can also be designed as a simple plate.

LIST OF REFERENCE NUMBERS

1

drive

2

engine

3

transmission

4

guide means

5

cover

6

adjustment

7

First fastening element

8th

Second fastening element

9

spindle

10

spindle nut

11

strip

12

limit switch

13

support rail

14

grinder carrier

15, 15 '

Nut body

16

inner thread

17, 17 ', 17' '

Federation

18

groove

19

Spindle nut portion

20

switching ring

21

switching lug

22

connecting element

23

guide element

24

fastening device

25

engaging member

26

guide element

27

fastening opening

28

admission

29a, b, c

conductor tracks

30

guide web

31

First chamber

32

Second Chamber

33

Molding

34

wiper contact

35

First leading edge

36

Second leading edge

37

encoder

38

contact point

a, b, c

connections

Claims (16)

Electromotive drive ( 1 ), in particular a furniture drive, comprising: - a guide device ( 4 ) guided, axially adjustable adjusting element ( 6 ), which with a first fastener ( 7 ) is connected for articulation to a furniture part to be adjusted; - a spindle ( 9 ) with one with the adjusting element ( 6 ) coupled spindle nut ( 10 ); - limit switch ( 12 ) for scanning end positions of the drive ( 1 ); and - one in the management facility ( 4 ) arranged device for scanning the displacement of the adjusting element ( 6 ) as an absolute displacement sensor, which with the adjusting element ( 6 ) and - that the means for scanning the displacement a support rail ( 13 ) with at least two tracks ( 29a to c), of which at least one has a certain electrical resistance; and - one in a slider carrier ( 14 ) arranged grinder contact ( 34 ), the conductor tracks ( 29a to c) the carrier rail ( 13 ), wherein the electrical resistance of the conductor tracks ( 29a to c) depending on the position of the adjusting element ( 6 ), characterized in that the conductor tracks ( 29a to c) on a lengthenable carrier rail ( 13 ) are applied, and wherein in the carrier rail ( 13 ) axially guided grinding carriers ( 14 ) with the adjusting element ( 6 ) is arranged and formed coupled, - that the slider carrier ( 14 ) with the spindle nut ( 10 ) is formed positively connectable, - that the positive connection of the grinding carrier ( 14 ) with the spindle nut ( 10 ) by means of a connecting element ( 22 ), and - that the guide device ( 4 ) is formed as a profiled tube made of metal or plastic and two parallel to the longitudinal axis of the guide device ( 4 ) running chambers ( 31 . 32 ), of which a first chamber ( 31 ) for receiving the limit switches ( 12 ) and its bar ( 11 ), and the carrier rail ( 13 ) in a second chamber ( 32 ) of the management facility ( 4 ) is arranged. Electromotive drive ( 1 ) according to claim 1, characterized in that the connecting element ( 22 ) has a spherical head which is in a corresponding receptacle ( 28 ) of the slider carrier ( 14 ) is formed einbringbar. Electromotive drive ( 1 ) according to claim 2, characterized in that the connecting element ( 22 ) on a switching ring ( 20 ) is formed, which with the spindle nut ( 10 ) is coupled. Electromotive drive ( 1 ) according to one of claims 1 to 3, characterized in that the drive ( 1 ) further comprises a releasable lock between the first fastening element ( 7 ) and the adjusting element ( 6 ), and that the switching ring ( 20 ) and the spindle nut ( 10 ) are formed rotatable against each other. Electromotive drive ( 1 ) according to claim 4, characterized in that the switching ring ( 20 ) with its outer jacket in the guide device ( 4 ) is guided. Electromotive drive ( 1 ) according to claim 5, characterized in that the outer diameter of the switching ring ( 20 ) is greater than the outer diameter of the spindle nut ( 10 ). Electromotive drive ( 1 ) according to one of claims 4 to 6, characterized in that the switching ring ( 20 ) with at least one engagement element ( 25 ) for engagement and for axial fixing with the spindle nut ( 10 ) is provided. Electromotive drive ( 1 ) according to one of claims 4 to 7, characterized in that the Switching ring ( 20 ) on the spindle nut ( 10 ) is designed clipped. Electromotive drive ( 1 ) according to one of claims 1 to 8, characterized in that the ablängbare carrier rail ( 13 ) at one end terminals (a, b, c) for electrically connecting the tracks ( 29a to c), and that the end opposite this end is cut to length. Electromotive drive ( 1 ) according to claim 9, characterized in that the cut-off end of the carrier rail ( 13 ) for an electrical connection of the tracks ( 29a to c) is formed with each other. Electromotive drive ( 1 ) according to one of claims 1 to 8, characterized in that the conductor tracks ( 29a to c) of each end of the carrier rail ( 13 ) for an electrical connection of the tracks ( 29a to c) are formed with one another and / or for an electrical connection to a control and evaluation unit by soldering, plugging and / or squeezing contacts. Electromotive drive ( 1 ) according to one of claims 1 to 11, characterized in that the carrier rail ( 13 ) or the management facility ( 4 ) a conductor track ( 29a to c) forms. Electromotive drive ( 1 ) according to one of claims 1 to 12, characterized in that the conductor tracks ( 29a to c) are integrated in a circuit as a variable resistor or as a voltage divider. Electromotive drive ( 1 ) according to claim 13, characterized in that the ratio of path change to resistance change is designed to be consistent. Electromotive drive ( 1 ) according to claim 13, characterized in that the ratio of path change to change in voltage of a voltage divider circuit is designed to be consistent. Electromotive drive ( 1 ) according to any one of claims 13 to 15, characterized in that the voltage difference between the respective end positions of the wearer ( 14 ) regardless of the length of the carrier rail ( 13 ) is formed substantially constant.

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